#version 330 layout (triangles) in; layout (triangle_strip, max_vertices = 5) out; // Needed for get_gl_Position uniform vec2 frame_shape; uniform vec2 pixel_shape; uniform float focal_distance; uniform float is_fixed_in_frame; uniform float anti_alias_width; uniform float flat_stroke; //Needed for lighting uniform vec3 light_source_position; uniform vec3 camera_position; uniform float joint_type; uniform float reflectiveness; uniform float gloss; uniform float shadow; in vec3 verts[3]; in float v_joint_angle[3]; in float v_stroke_width[3]; in vec4 v_color[3]; out vec4 color; out float uv_stroke_width; out float uv_anti_alias_width; out float has_prev; out float has_next; out float bezier_degree; out vec2 uv_coords; out vec2 uv_b2; // Codes for joint types const float AUTO_JOINT = 0; const float ROUND_JOINT = 1; const float BEVEL_JOINT = 2; const float MITER_JOINT = 3; const float PI = 3.141592653; const float DISJOINT_CONST = 404.0; #INSERT quadratic_bezier_geometry_functions.glsl #INSERT get_gl_Position.glsl #INSERT get_unit_normal.glsl #INSERT finalize_color.glsl void create_joint(float angle, vec2 unit_tan, float buff, vec2 static_c0, out vec2 changing_c0, vec2 static_c1, out vec2 changing_c1){ float shift; if(abs(angle) < 1e-3){ // No joint shift = 0; }else if(joint_type == MITER_JOINT){ shift = buff * (-1.0 - cos(angle)) / sin(angle); }else{ // For a Bevel joint shift = buff * (1.0 - cos(angle)) / sin(angle); } changing_c0 = static_c0 - shift * unit_tan; changing_c1 = static_c1 + shift * unit_tan; } // This function is responsible for finding the corners of // a bounding region around the bezier curve, which can be // emitted as a triangle fan int get_corners( vec2 controls[3], int degree, float stroke_widths[3], float angle_from_prev, float angle_to_next, out vec2 corners[5] ){ vec2 p0 = controls[0]; vec2 p1 = controls[1]; vec2 p2 = controls[2]; // Unit vectors for directions between control points vec2 v10 = normalize(p0 - p1); vec2 v12 = normalize(p2 - p1); vec2 v01 = -v10; vec2 v21 = -v12; vec2 p0_perp = vec2(-v01.y, v01.x); // Pointing to the left of the curve from p0 vec2 p2_perp = vec2(-v12.y, v12.x); // Pointing to the left of the curve from p2 // aaw is the added width given around the polygon for antialiasing. // In case the normal is faced away from (0, 0, 1), the vector to the // camera, this is scaled up. float aaw = anti_alias_width * frame_shape.y / pixel_shape.y; float buff0 = 0.5 * stroke_widths[0] + aaw; float buff2 = 0.5 * stroke_widths[2] + aaw; float aaw0 = (1 - has_prev) * aaw; float aaw2 = (1 - has_next) * aaw; vec2 c0 = p0 - buff0 * p0_perp + aaw0 * v10; vec2 c1 = p0 + buff0 * p0_perp + aaw0 * v10; vec2 c2 = p2 + buff2 * p2_perp + aaw2 * v12; vec2 c3 = p2 - buff2 * p2_perp + aaw2 * v12; // Account for previous and next control points if(has_prev > 0) create_joint(angle_from_prev, v01, buff0, c0, c0, c1, c1); if(has_next > 0) create_joint(angle_to_next, v21, buff2, c3, c3, c2, c2); // Linear case is the simplest if(degree == 1){ // The order of corners should be for a triangle_strip. Last entry is a dummy corners = vec2[5](c0, c1, c3, c2, vec2(0.0)); return 4; } // Otherwise, form a pentagon around the curve float orientation = sign(cross2d(v01, v12)); // Positive for ccw curves if(orientation > 0) corners = vec2[5](c0, c1, p1, c2, c3); else corners = vec2[5](c1, c0, p1, c3, c2); // Replace corner[2] with convex hull point accounting for stroke width corners[2] = corners[2] - orientation * (buff0 * p0_perp + buff2 * p2_perp); return 5; } void main() { if (distance(verts[0], verts[1]) == 0 && distance(verts[1], verts[2]) == 0) return; bezier_degree = (abs(v_joint_angle[1]) < 1e-3) ? 1.0 : 2.0; vec3 unit_normal = get_unit_normal(vec3[3](verts[0], verts[1], verts[2])); // Adjust stroke width based on distance from the camera float scaled_strokes[3]; for(int i = 0; i < 3; i++){ float sf = perspective_scale_factor(verts[i].z, focal_distance); if(bool(flat_stroke)){ vec3 to_cam = normalize(vec3(0.0, 0.0, focal_distance) - verts[i]); sf *= abs(dot(unit_normal, to_cam)); } scaled_strokes[i] = v_stroke_width[i] * sf; } // Control points are projected to the xy plane before drawing, which in turn // gets tranlated to a uv plane. The z-coordinate information will be remembered // by what's sent out to gl_Position, and by how it affects the lighting and stroke width vec2 flat_controls[3]; for(int i = 0; i < 3; i++){ float sf = perspective_scale_factor(verts[i].z, focal_distance); flat_controls[i] = sf * verts[i].xy; } // If the curve is flat, put the middle control in the midpoint if (bezier_degree == 1.0){ flat_controls[1] = 0.5 * (flat_controls[0] + flat_controls[2]); } // Set joint information float angle_from_prev = v_joint_angle[0]; float angle_to_next = v_joint_angle[2]; has_prev = 1.0; has_next = 1.0; if(angle_from_prev == DISJOINT_CONST){ angle_from_prev = 0.0; has_prev = 0.0; } if(angle_to_next == DISJOINT_CONST){ angle_to_next = 0.0; has_next = 0.0; } // Corners of a bounding region around curve vec2 corners[5]; int n_corners = get_corners( flat_controls, int(bezier_degree), scaled_strokes, angle_from_prev, angle_to_next, corners ); int index_map[5] = int[5](0, 0, 1, 2, 2); if(n_corners == 4) index_map[2] = 2; // Find uv conversion matrix mat3 xy_to_uv = get_xy_to_uv(flat_controls[0], flat_controls[1]); float scale_factor = length(flat_controls[1] - flat_controls[0]); uv_anti_alias_width = anti_alias_width * frame_shape.y / pixel_shape.y / scale_factor; uv_b2 = (xy_to_uv * vec3(flat_controls[2], 1.0)).xy; // Emit each corner for(int i = 0; i < n_corners; i++){ uv_coords = (xy_to_uv * vec3(corners[i], 1.0)).xy; uv_stroke_width = scaled_strokes[index_map[i]] / scale_factor; // Apply some lighting to the color before sending out. vec3 xyz_coords = vec3(corners[i], verts[index_map[i]].z); color = finalize_color( v_color[index_map[i]], xyz_coords, unit_normal, light_source_position, camera_position, reflectiveness, gloss, shadow ); gl_Position = vec4( get_gl_Position(vec3(corners[i], 0.0)).xy, get_gl_Position(verts[index_map[i]]).zw ); EmitVertex(); } EndPrimitive(); }